Greatest advances in cardiology in the 20th century
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Transcript Greatest advances in cardiology in the 20th century
The 10 Greatest
Advances in Cardiology in
th
the 20 century
Dr. Antoinette Cilliers
Department of Paediatrics and Child Health
1. Electrocardiogram
ECG
The ECG measures the electrical
activity of the heart.
This includes:
• the rate and regularity of beats
• the size and position of the
chambers
• any damage to the heart and
• effects of drugs or devices to
regulate the heart.
Each heartbeat in a normally functioning
heart exhibits a similar characteristic
pattern consisting of five waves referred to
as P, Q, R, S and T.
History
• 1856 - von Koelliker and Müller first to discover that the heart
generated electricity.
• 1887 - Waller published first report of a recording of cardiac
electricity on the body's surface; called the recording a
“cardiograph.”
William Einthoven, observed Waller demonstrating
the use of the capillary electrometer to record an
“electrograph” of the heart.
In 1895, he was able to detect recognizable waves,
which he labelled “P, Q, R, S, and T.” Formulated the
concept of “Einthoven's triangle” by mathematically
relating the 3 leads (Lead III = Lead II – Lead I).
He described bigeminy, complete heart block, “P
mitrale,” right and left and ventricular hypertrophy, atrial
fibrillation and flutter, the U wave, and examples of
various heart diseases
The “father of electrocardiography” was honoured with
the Nobel Prize in Medicine in 1924.
2. Echocardiography
Echocardiogram
An echocardiogram is an
ultrasound scan of the heart.
Jelly is applied to the chest wall
and an ultrasound probe is placed
on the chest wall to build up a
picture of the function and
structure of the heart.
It can measure the effectiveness
of the pumping action of the heart
and how efficiently the heart
valves are working.
This investigation is done as an
out patient appointment.
History of
Echocardigraphy
1880 - Pierre and Jacques Curie discovered piezoelectricity.
During World War II, the field of sonar ultrasonography
advanced rapidly because of its use for detecting submarines.
The pioneers of echocardiography were Inge Edler, a Swedish
cardiologist and Hellmuth Hertz, a Swedish physicist.
Edler and Hertz borrowed a sonar device from a local shipyard,
improved it, and recorded cardiac echoes from Hertz's own
heart.
They first reported the continuous recording of movements of
the heart walls in 1954 and described the use of the ultrasonic
cardiogram for mitral valve diseases in 1956.
Echocardiography
• With the development of Doppler
echocardiography in the 1960s, the
ink-jet printer (another invention by
Hertz) was useful in the
development of the colour Doppler
technique.
• In 1977, Edler and Hertz were
joint recipients of the Lasker Prize,
which is the American equivalent of
the Nobel Prize in Medicine.
3. Cardiac Catheterization
and Coronary Angiography
Angiogram
This is carried out by injecting a dye which can be
seen on X-ray into the coronary arteries via a
catheter which is fed into the femoral artery
(groin) or brachial artery (arm).
The area is first treated with local anaesthetic.
A series of x-rays are taken to determine the
percentage of narrowing of the three branches of
the coronary artery.
This investigation is usually done as a day case,
but occasionally an overnight stay in hospital is
necessary.
Cardiac Catheterization and
Coronary Angiography
1844 - Claude Bernard, a noted French research physiologist,
used catheters to record intracardiac pressures in animals and
coined the term “cardiac catheterization.”
With the discovery of x-rays in 1895 by Wilhelm Roentgen, a new
approach to the study of cardiac anatomy became possible.
1907 - Two German physicians, Friedrich Jamin and Hermann
Merkel, published the 1st roentgenographic atlas of the human
coronary arteries in. Study of 29 hearts in which the coronary
arteries were injected with a suspension of red lead in gelatin.
1929 - a young surgical resident, Werner Forssmann, performed
the 1st documented human cardiac catheterization on himself in
Germany. He anaesthetized his left elbow, inserted a catheter
into his antecubital vein, and confirmed the position of the
catheter tip in the right atrium by use of radiography. His goal
was to find a safe and effective way to inject drugs for cardiac
resuscitation.
Cardiac Catheterization and
Coronary Angiography
Forssmann next injected contrast material through a catheter
placed in the right atrium. His contributions, along with the
development of nontoxic contrast media and the steady
advances in radiological techniques, prepared the way for the
development of coronary angiography.
1941 - Cournand and Richards used cardiac catheter as a
diagnostic tool for the 1st time, applying catheterization
techniques to measure right-heart pressures and cardiac output.
For their landmark work, they shared a Nobel Prize in Medicine
with Forssmann in 1956.
1958 - Mason Sones performed selective coronary arteriography
in a series of more than 1,000 patients. This development
initiated a period of rapid growth in coronary arteriography
during the mid 1960s.
Melvin Judkins, a radiologist who had studied coronary
angiography with Sones, created his own system of coronary
imaging in 1967, introducing a series of specialized catheters
and perfecting the transfemoral approach.
4. Framingham heart
study
Framingham study
The Framingham Study is one of the most impressive medical works
in the 20th century. During the 1st half of the century, there was a
steady increase in deaths attributed to heart disease. However, the
causes of coronary heart disease were speculative.
With support from the newly created National Heart Institute (now
National Heart, Lung, and Blood Institute [NHLBI]), the 1st
collection of information from a community cohort was gathered.
Between 1948 and 1951, 1980 men and 2421 women were enrolled
in an observational study in Framingham, Massachusetts.
The 1st report of this long-term study, “Factors of risk in the
development of coronary heart disease - six-year follow-up
experience”; was published in 1961.
The study showed that high blood pressure, smoking, and high
cholesterol levels were major factors in heart disease. From this
report, the concept of risk factors emerged.
Framingham study
The Framingham Study provided information crucial to the recognition
and management of atherosclerosis, its causes, and its complications.
Fifty years' worth of data collected from the residents of Framingham
has
– produced over 1,000 scientific papers;
– introduced the concepts of biologic, environmental, and behavioral
risk factors;
– identified major risk factors associated with heart disease, stroke,
and other diseases;
– created a revolution in preventive medicine; and
– forever changed the ways in which the medical community and the
general population view the genesis of disease.
First cardiovascular study that included women participants.
Has served as the model for many other longitudinal cohort studies.
5. “Lipid Hypotheses” and
Atherosclerosis
Lipids and atherosclerosis
During the 19th century- arteriosclerosis well recognized, but its
etiologic and pathologic significance not established.
Hypotheses – e.g. disturbed arterial metabolism, adherent
blood clots that gradually changed into arteriosclerotic plaques.
1904 - Felix Marchand introduced the term atherosclerosis;
suggested atherosclerosis was responsible for nearly all
obstructive processes in arteries.
1908 – a Russian, Ignatowski, observed possible relation
between cholesterol-rich foods and experimental atherosclerosis.
1910 - Adolf Windaus showed that atheromatous lesions
contained 6 times as much free cholesterol as a normal arterial
wall and 20 times more esterified cholesterol.
1913- Using cholesterol-fed rabbits to produce experimental
atherosclerosis, Nikolai Anichkov demonstrated that cholesterol
alone that caused these atherosclerotic changes in the rabbit
intima. Found early lesions, such as fatty streaks, as well as
advanced lesions; and discovered that the amount of cholesterol
uptake was directly proportional to the degree of atherosclerosis
severity.
Lipids and atherosclerosis
1950 -Gofman identified the low-density lipoprotein (LDL)
cholesterol and high-density lipoprotein (HDL) cholesterol using
the ultracentrifuge technique. Found that 101 of 104 men with
myocardial infarction had elevated LDL molecules— similar to
their cholesterol-fed atherosclerotic rabbits. Gofman's group
observed an inverse relationship between HDLs and risk of
coronary artery disease.
1952 - Kinsell - ingestion of plant foods and avoidance of animal
fats decreased the blood level of cholesterol.
Framingham Study - showed that the risk of developing clinically
significant coronary artery disease was a continuous curvilinear
function of blood cholesterol levels.
During the 1950s and 1960s- many cholesterol-lowering agents
were introduced into clinical use, including nicotinic acid,
cholestyramine, clofibrate, and plant sterols.
1961- the American Heart Association began encouraging people
to follow a “prudent diet”
Lipids and atherosclerosis
1964 - Bloch and Lynen received the Nobel Prize in Medicine
for their work on the metabolism of cholesterol and fatty
acids.
1970s - Brown and Goldstein identified the LDL receptor and
the LDL pathway and shared the 1985 Nobel Prize in
Medicine.
Major breakthrough in the pharmacologic management of
hypercholesterolemia was the discovery of the statins (3hydroxy-3-methylglutaryl coenzyme A reductase inhibitors).
Akira Endo in Japan discovered the earliest statin, compactin,
in 1976.
1985 - the NHLBI established the National Cholesterol
Education Program to educate both physicians and patients
about the importance of treating hypercholesterolemia, and
the 1st guidelines were published in 1988.
6. Coronary Care Units
Coronary care units
Early 1960s - technique of closed-chest cardiopulmonary
resuscitation and continuous telemetry monitoring with an alarm
system laid the groundwork for coronary care units (CCUs)—
specialized intensive care units for patients with acute myocardial
infarctions (MIs).
These developments were combined with 2 simple strategies:
– 1) the clustering of patients with MIs on a single hospital unit, where
necessary equipment and drugs were readily available and where
trained personnel could be in continuous attendance; and
– 2) the training of specialized nurses to recognize and treat
arrhythmias rapidly in the absence of a physician.
Major objective was to reduce the number of deaths caused by
arrhythmias.
However, no measures were available to manage overwhelming
shock or refractory pulmonary oedema resulting from pump
failure.
Coronary care units
Desmond Julian presented the 1st description of the CCU to
the British Thoracic Society in 1961.
1962- Bauer and White started a CCU in a Sydney hospital.
1967 - Killip and Kimball published their experience consisting
of 250 patients with MIs who had been treated in the CCU.
Compared with other patients who had experienced MIs,
those treated in the CCU had better survival rates in the
absence of cardiogenic shock.
From experience in early CCUs, it soon became apparent that
arrhythmias were much more common than had previously
been suspected. Ventricular extrasystoles were found to be
almost universal and generated a lot of interest as “warning”
arrhythmias.
Coronary care units
Bernard Lown and colleagues reported that they found no
occurrence of ventricular fibrillation when patients who
experienced warning arrhythmias were treated with lidocaine.
1967 - The development of CCUs coincided with a rapid
expansion in the use of transvenous pacing, which was
performed in 35% of patients with MIs in one centre in New York
Early success in CCUs with resuscitation and with the detection
and treatment of arrhythmias focused researchers' attention on
left ventricular failure and cardiogenic shock.
The Myocardial Infarction Research Units were created in the
United States by the NHLBI, and a large program of research was
initiated for the investigation of the hemodynamic effects of
myocardial infarction.
The Swan-Ganz flow-guided catheter was introduced, and its use
for invasive monitoring of cardiac hemodynamics became routine
in some centres.
7. Thrombolytic Therapy
Thrombolytic Therapy
1933 - Tillet and Garner discovered that Group A β-haemolytic
streptococci produced a fibrinolytic substance (streptococcal
fibrinolysin).
1941 - Milstone suggested that a plasma factor, which he called a
“plasma lysing factor,” was necessary for streptococcal-mediated
fibrinolysis.
1945 - Christensen, a microbiologist, was able to describe the
entire mechanism of streptococcal fibrinolysis. Showed human
plasma contained the precursor of an enzyme system, which he
called plasminogen, and that the streptococcal fibrinolysin, which
he named streptokinase, was an activator that could convert
plasminogen to the proteolytic and fibrinolytic enzyme plasmin.
1947- Christensen made available to Tillet a crudely purified
preparation of streptokinase. Animal experiments with
streptokinase in order to determine its efficacy in the treatment of
acute coronary thrombosis.
1952 - Tillet and Johnson reported lysis of experimental thrombi in
rabbits' ears with intravenous streptokinase administered through
a peripheral vein.
Thrombolytic Therapy
1957 - Sherry reported a rational approach to thrombolysis
using a loading dose and a sustained infusion of streptokinase
sufficient to increase the clot-dissolving activity of plasma by
several hundred-fold.
1958 - 1st study of intravenously administered streptokinase
performed in patients who had MIs.
DeWood provided angiographic evidence of a very high
incidence of total occlusion of infarct-related arteries during
the early period of infarction, and
Rentrop demonstrated rapid recanalization after local
administration of streptokinase directly into an infarct-related
artery.
Thereafter, the Netherlands trial, the Western Washington
trials, and ISIS-2 demonstrated both short- and long-term
benefits of thrombolytic therapy.
8. Open-Heart Surgery
Open-Heart Surgery
1849- Wilfred Bigelow and his team performed open-heart
procedures in animals with the use of hypothermia
1953 - John Lewis performed the 1st successful closure of an
atrial septal defect in a 5-year-old girl, using the open-heart
hypothermic technique that Bigelow's group had developed.
1953 - The heart-lung machine, which offered additional
protection to vital organs, used by John Gibbon during the
repair of an atrial septal defect.
1956 - Walton Lillehei and his team corrected pure mitral
regurgitation with suture plication of the commissures under
direct vision.
After that time, many surgeons around the world became
involved in direct vision repair, and prosthetic valves were
introduced for cardiac valve replacement.
Open-Heart Surgery
1935 - Claude Beck published his classic paper, “The development of
a new blood supply to the heart by operation,” which described his
technique of grafting a flap of the pectoralis muscle over the exposed
epicardium to create a new blood supply.
1946 - Vineberg used the internal mammary artery to provide a new
source of blood to the myocardium. Technique became very popular;
about 5,000 such operations performed between 1950 and 1970.
1964 - Vasilii Kolessov, a Russian cardiac surgeon, performed the 1st
internal mammary artery–coronary artery anastomosis.
1967 - René Favaloro achieved a physiologic approach in the surgical
management of coronary artery disease—the bypass grafting
procedure. Used a saphenous vein autograft to replace a stenotic
segment of the right coronary artery. Began to use the saphenous
vein as a bypassing channel. Soon Dudley Johnson extended the
bypass procedure to include the left coronary arterial systems.
1968 – Use of the internal mammary artery instead of the saphenous
vein for bypass grafting.
Today, coronary artery bypass grafting has become one of the most
common operations and is performed all over the world.
9. Automatic Implantable
Cardiac Defibrillators
Automatic Implantable
Cardiac Defibrillators
1775 - 1st successful attempt at electrical defibrillation. Peter
Abildgaard, a Danish veterinarian, evaluated the effects of
electrical shock and countershock on chickens.
1899 - Prevost and Batelli noted that if shock was applied within
seconds of the onset of fibrillation, the result was defibrillation,
which successfully restored sinus rhythm.
1932 - Original concept of the artificial pacemaker is attributed
to Albert Hyman
1947 - Beck first to apply electrical defibrillation to a human
heart in the operating room.
1950- Bigelow, Callaghan and Hopps developed a technique of
transvenous pacing.
Smith and Stone Ltd. built the 1st commercial pacemaker to
their design.
1956 - Zoll and co-workers performed the 1st successful external
defibrillation in a human subject.
Automatic Implantable
Cardiac Defibrillators
1958 - In Sweden, Senning and Elmqvist designed a miniature pulse
generator, which was implanted after a thoracotomy.
Greatbatch, in the United States, devised an implantable pacemaker
powered by a mercury-zinc battery.
1962 - The early devices were all asynchronous; the 1st
atrioventricular (AV) synchronous pacemaker, which simulated a true
physiologic state, was implanted.
These achievements and the expanding knowledge of clinical
electrophysiology led to the invention of the automatic implantable
cardiac defibrillator (AICD).
This device was meant to abort ventricular fibrillation at its onset,
thus averting the inevitably fatal outcome.
Automatic Implantable
Cardiac Defibrillators
Mirowski, Mower, and Staewen at Sinai Hospital of Baltimore
collaborated on the AICD in 1969. The concept of the AICD
generated a lot of criticism, but the Baltimore group continued
to pursue their research.
Heilman joined that group in 1972. He helped make sensing
circuits that could identify ventricular fibrillation on the basis of a
mathematical formula called the probability density function.
1980 - after extensive animal research, Mirowski's team
successfully treated their 1st human patient with an AICD. In
their first 50 patients, the mortality rate was less than 10%.
Soon the AICD became the treatment of choice for patients with
life-threatening ventricular tachyarrhythmias by consistently
outperforming the best medications available for these patients.
10. Coronary Angioplasty
Coronary Angioplasty
1964 - Charles Dotter and Melvin Judkins described a new
technique for relieving stenosis of the iliofemoral arteries with
rigid dilators.
The procedure was largely ignored in the US because of
technical difficulties and complications but used to treat large
numbers of patients in Europe.
1974 - In Zurich, Andreas Gruentzig substituted a balloontipped catheter for the rigid dilator and performed the 1st
peripheral balloon angioplasty in a human being.
After achieving success with coronary angioplasty in animals,
Gruentzig and his colleagues performed the 1st intraoperative
balloon angioplasty on the human heart. Soon, Gruentzig
accomplished the 1st coronary angioplasty in a patient who
was awake.
Coronary Angioplasty
1977 - Gruentzig performed balloon angioplasty on an isolated
stenosis of the proximal left anterior descending coronary
artery. The Gruentzig technique took the cardiology
community by storm, and the era of interventional cardiology
was born.
An international registry of PTCA was established to provide a
method for systematic evaluation of this new procedure.
Even after Gruentzig's death in 1985, his technique continued
to evolve and subsequently led to applications such as
coronary atherectomy (1986) and coronary stenting (1987).
By 1997, angioplasty had become one of the most common
medical interventions in the world.